Associations of aspirin, statins and metformin with lung cancer risk and related mortality

Context

Cardiovascular diseases (CVDs), including ischaemic heart disease and cerebrovascular disease, are the leading cause of death in both sexes worldwide, followed by cancer [1, 2]. Most CVDs can be prevented by addressing behavioural risk factors, such as tobacco smoking, unhealthy diets, obesity, physical inactivity and harmful use of alcohol [3]. Individuals with CVDs or those at high cardiovascular risk due to the presence of one or more risk factors (e.g. arterial hypertension, diabetes, hyperlipidaemia and obesity) require early detection and management [3]. Counselling and medicines should be offered, as appropriate. These shared metabolic and behavioural risk factors are causatively linked to the development of heart disease, stroke, cancer, diabetes and respiratory diseases [3]. Lung cancer is, by far, the most common cause of cancer-related death worldwide [3, 4]. Given that lung cancer patients may initially present with cardiovascular and/or metabolic comorbidities at the time of cancer diagnosis, questions have been raised as to whether long-term use of combined medications to treat these diseases affects the incidence and mortality of lung cancer patients on a population-based level.

Established oral therapies are currently the cornerstone of prevention of cardiovascular and metabolic diseases, and include: 1) the anti-thrombotic agent acetylsalicylic acid (also known as aspirin) for reducing CVD morbidity and mortality among survivors of myocardial infarction and stroke; 2) the glucose-lowering agent metformin as the first-line therapeutic agent for type 2 diabetes (T2D); and 3) the lipid-lowering statins as effective drugs for reducing the risk of myocardial infarction, ischaemic stroke, and development of peripheral arterial disease.

The impact of these medications on the present management of cardiovascular and metabolic diseases is emphasised by the fact that these agents are in the World Health Organization model list of essential medicines [5].

Over the past few decades, these groups of drugs have commonly been prescribed together as a measure of chemoprevention given the close interconnection between cardiovascular disease, diabetes and dyslipidaemia [3, 6]. Nevertheless, in the literature to date, both observational and randomised controlled trials (RCTs) have merely assessed the individual potential effects of each of these three types of agents, without taking into account their combined effect, dose–response relationship or time-dependent exposure [7–10]. The study to be discussed here by Kang et al. [11] has shed some light on the latter.

Main results

After the 10-year follow-up period, a total of 5990 lung cancer cases and 5938 deaths from lung cancer over the follow-up years was observed. Of the 732 199 participants, 9.0% (n=66 024), 5.1% (n=37 031) and 6.3% (n=46 205) were ever users of aspirin, statins or metformin, respectively. Moreover, 6.3% (n=46 205) of all participants were diagnosed with T2D, of which 55.8% were ever on metformin.

There was no significant association between ever use of aspirin and incidence of lung cancer or lung cancer-related mortality. Nevertheless, aspirin showed a risk reduction for deaths of lung cancer patients when taken for ≥1.5 years.

Lung cancer incidence was not associated with ever use or cDDD use of statins. However, a dose-dependent reduction in lung cancer-related mortality was observed with increased cDDD of statin use; a cumulative use of statins for ≥1.5 years led to a relative risk reduction of 23%. Ever use of metformin was significantly associated with reduced incidence of lung cancer compared with non-diabetic patients (adjusted hazard ratio (aHR) 0.89). Diabetic patients with a cumulative metformin use of ≥1.5 years showed both a decreased lung cancer incidence (aHR 0.44) and mortality (aHR 0.76) compared to diabetic patients who did not take metformin. In a dose-dependent manner among diabetic patients, metformin use had a protective association with lung cancer incidence and mortality. The association between metformin and decreased lung cancer mortality was strongest in nonsmokers (aHR 0.41 in the group with ≥1.5 years of cDDD) and women (aHR 0.19 in the group with ≥1.5 years of cDDD) compared with the entire cohort.

Concomitant use of aspirin, statins and metformin appeared to protect against the development of lung cancer or lung cancer death. Ever users of this combination regimen were associated with decreased lung cancer incidence (aHR 0.83) and mortality (aHR 0.83) compared to never users. The magnitude of the effect increased progressively with a longer duration of combined medication exposure. Those subjects with ≥1.5 years of combination drug use showed the lowest risk for developing lung cancer (aHR 0.49) and associated mortality (aHR 0.42). Smoking status did not influence these inverse associations. Table 1 summarises the main results.

Commentary

Prevention of lung cancer is a priori the pivotal measure to reduce the numerous morbidities and enormous mortality in patients with lung cancer, as well as its burden on individual patients, their families and society. The most effective preventive measure is tobacco cessation since the causal chain for tobacco smoking leading to lung cancer is well established, accounting for about 80–90% of all lung cancer cases [12].

A further preventive strategy is chemoprevention, i.e. the use of dietary or pharmaceutical interventions to slow or reverse the progression of premalignancy to invasive cancer [13, 14]. Preventive measures apply to common diseases and are generally aimed at: 1) primary prevention: subjects who are at high risk (current or former smokers), but without evidence of a disease, e.g. lung cancer or CVD; 2) secondary prevention: subjects who have risk factors and show evidence of early stage disease, e.g. premalignancy; and 3) tertiary prevention: subjects with pre-existing, risk factor-related diseases (e.g. lung cancer, CVD) to prevent secondary events (e.g. second primary tumour, myocardial infarction, stroke).

The rationale for chemoprevention is based on two main concepts: 1) multistep carcinogenesis (a series of genetic and epigenetic alterations leading to malignant transformation from normal cells to precursor cells and then to invasive tumour cells); and 2) field cancerisation (assuming that many areas of the aerodigestive tract are simultaneously at risk of cancer formation due to carcinogen exposure) [14, 15].

As reviewed by the authors, long-term follow-up data from some trials of these drugs in the treatment and prevention of CVD, diabetes or dyslipidaemia have provided an opportunity to explore their possible benefits on cancer incidence and mortality. Unfortunately, Cochrane-initiated systematic reviews and meta-analyses investigating the anti-tumour effects of these agents alone or in combination in patients with lung cancer are still not yet available. The latest analysis on the chemoprevention of lung cancer was published within the American College of Chest Physicians evidence-based clinical practice guidelines in 2013. It concluded that none of the phase 3 trials with these agents, including aspirin or metformin, provided sufficient evidence to be used in the chemoprevention of lung cancer so far [14].

Implication for practice

This study brings more data to the mounting evidence that the use of metformin seems to be beneficial with regards to survival in patients with lung cancer. Furthermore, it brings innovative data with regards to aspirin, statins and especially the combination of aspirin, statins, and metformin in terms of lung cancer incidence and mortality in a large population-based cohort.

Although these results seem promising, the direct implications for current clinical practice remain unclear as several questions persist. For instance, due to the nature of the observational study, more evidence is needed before aspirin, statins or metformin alone, or their combinations, can be offered to patients to prevent lung cancer (i.e. chemoprevention). It is also not possible at this time, based on the data in the study, to recommend that aspirin, statins or metformin alone, or in combination, should be offered to patients with lung cancer as a means of tertiary prevention.

Therefore, research should be encouraged in this field by conducting RCTs to determine whether these drugs really do have a preventive effect and can offer mortality reduction. These trials would need to focus on which drug alone or in a drug-drug association effectively reduces lung cancer incidence and mortality. Furthermore, the duration of the chosen treatments should also be explored as well as the dose and the date of introduction of the medication(s) with respect to the date of cancer diagnosis. These studies would most likely be challenging to perform in terms of time and related costs, but could provide crucial answers related to the field of lung cancer prevention and treatment. Perhaps future lung cancer guidelines will be able to address the questions of chemoprevention by means of high quality observational and treatment studies.